Diversity and evolution of mitochondrial RNA editing systems

'RNA editing' describes the programmed alteration of the nucleotide sequence of an RNA species, relative to the sequence of the encoding DNA. The phenomenon encompasses two generic patterns of nucleotide change, 'insertion/deletion' and 'substitution', defined on the basis of whether the sequence of the edited RNA is colinear with the DNA sequence that encodes it. RNA editing is mediated by a variety of pathways that are mechanistically and evolutionarily unrelated. Messenger, ribosomal, transfer and viral RNAs all undergo editing in different systems, but well-documented cases of this phenomenon have so far been described only in eukaryotes, and most often in mitochondria. Editing of mRNA changes the identity of encoded amino acids and may create translation initiation and termination codons. The existence of RNA editing violates one of the long-accepted tenets of genetic information flow, namely, that the amino acid sequence of a protein can be directly predicted from the corresponding gene sequence. Particular RNA editing systems display a narrow phylogenetic distribution, which argues that such systems are derived within specific eukaryotic lineages, rather than representing traits that ultimately trace to a common ancestor of eukaryotes, or even further back in evolution. The derived nature of RNA editing raises intriguing questions about how and why RNA editing systems arise, and how they become fixed as additional, essential steps in genetic information transfer.     

Maxicircle (mitochondrial) genome sequence (partial) of Leishmania major: gene content, arrangement and composition compared with Leishmania tarentolae

We report 8420 bp of DNA sequence data from the maxicircle (mitochondrial) genome of Leishmania major (MHOM/SU/73/5ASKH), a much larger portion of this genome than has been reported previously from any Leishmania species infecting humans. This region contains 10 partial and complete genes: 5 protein-encoding genes (COII, COIII, ND1, ND7 and Cyt b); two ribosomal RNA subunits (12S and 9S) and three unidentified open reading frames (MURF1, MURF4 (ATPase6) and MURF5), as in the lizard-infecting species L. tarentolae. The genes from L. major exhibit 85-87% identity with those of L. tarentolae at the nucleotide level and 71-94% identity at the amino acid level. Most differences between sequences from the two species are transversions. The gene order and arrangement within the maxicircle of L. major are similar to those in L. tarentolae, but base composition and codon usage differ between the species. Codons assigned for initiation for protein-coding genes available for comparison are similar in five genes in the two species. Pre-editing was identified in some of the protein-coding genes. Short intergenic non-coding regions are also present in L. major as they are in L. tarentolae. Intergenic regions between 9S rRNA and MURF5, MURF1 and ND1 genes are G+C rich and considered to be extensive RNA editing regions. The RNA editing process is likely to be conserved in similar pattern in L. major as in L. tarentolae.     

RNA editing of wheat mitochondrial ATP synthase subunit 9: direct protein and cDNA sequencing.

RNA editing of subunit 9 of the wheat mitochondrial ATP synthase has been studied by cDNA and protein sequence analysis. Most of the cDNA clones sequenced (95%) showed that editing by C-to-U transitions occurred at eight positions in the coding region. Consequently, 5 amino acids were changed in the protein when compared with the sequence predicted from the gene. Two edited codons gave no changes (silent editing). One of the C-to-U transitions generated a stop codon by modifying the arginine codon CGA to UGA. Thus, the protein produced is 6 amino acids shorter than that deduced from the genomic sequence. Minor forms of cDNA with partial or overedited sequences were also found. Protein sequence and amino acid composition analyses confirmed the results obtained by cDNA sequencing and showed that the major form of edited atp9 mRNA is translated.     

Phylogenetic Affinity of Mitochondria of Euglena gracilis and Kinetoplastids Using Cytochrome Oxidase I and hsp60

The mitochondrial DNA-encoded cytochrome oxidase subunit I (COI) gene and the nuclear DNA-encoded hsp60 gene from the euglenoid protozoan Euglena gracilis were cloned and sequenced. The COI sequence represents the first example of a mitochondrial genome-encoded gene from this organism. This gene contains seven TGG tryptophan codons and no TGA tryptophan codons, suggesting the use of the universal genetic code. This differs from the situation in the mitochondrion of the related kinetoplastid protozoa, in which TGA codes for tryptophan. In addition, a complete absence of CGN triplets may imply the lack of the corresponding tRNA species. COI cDNAs from E. gracilis possess short 5′ and 3′ untranslated transcribed sequences and lack a 3′ poly[A] tail. The COI gene does not require uridine insertion/deletion RNA editing, as occurs in kinetoplastid mitochondria, to be functional, and no short guide RNA-like molecules could be visualized by labeling total mitochondrial RNA with [α-³²P]GTP and guanylyl transferase. In spite of the differences in codon usage and the 3′ end structures of mRNAs, phylogenetic analysis using the COI and hsp60 protein sequences suggests a monophyletic relationship between the mitochondrial genomes of E. gracilis and of the kinetoplastids, which is consistent with the phylogenetic relationship of these groups previously obtained using nuclear ribosomal RNA sequences. Received: 5 March 1996 / Accepted: 31 July 1996